Scanner assembly with removable shock mount

ABSTRACT

An indicia scanning assembly having a housing with a shock mount receiving space; and an elastomeric scan engine receiving shock mount positioned in the shock mount receiving space. The scan engine receiving shock mount has a first end with a scan engine receiving space.

FIELD OF THE INVENTION

The invention is generally related to a scanner assembly, and, more specifically, to a barcode scanner assembly having a removable shock mount.

BACKGROUND

The use of image sensor based scanners (“scanners”) is well known in the art for the purposes of decoding information encoded in barcode symbols (also known as indicia). For decoding a barcode symbol, images are generally captured by a scan engine positioned in the scanner, with the captured image being subject to processing by an application of one or more barcode decoding algorithms.

A variety of different scanning mechanisms are used to capture and read an image of a barcode, with each type of scanning mechanism being performed by a specific type of scan engine. A conventional scanner is generally designed with a scanner housing having an integrated scan engine. The disadvantage of the conventional scanner is that scan engines each have a unique footprint, requiring specific structural features to integrate them into the scanner housing. A further disadvantage of the conventional scanner is that each scan engine frequently requires a specific type of window and window orientation to properly function. Thus, the scanner housing must be specially manufactured to include the specific structural features for each type of scan engine and window configuration when developing families of scanners. This approach greatly increases both the manufacturing cost and lead times when a new scan engine needs to be integrated into the housing.

Attempts have been made to design scanners with universal housings that accept interchangeable scan modules having different scan engines. However, the interchangeable scan modules are very complex in design, including a scan engine mounted to a bracket and a printed circuit board, and being positioned in a rigid housing having a bezel and an attached window. Such designs are complicated, increasing manufacturing costs and production time. Additionally, the large number of components correspondingly introduces a large number of interfaces that contribute to a stack up tolerance that decreases sensitivity of the scanner, or even renders the scanner unusable for some types of scan engines.

SUMMARY

Accordingly, in one aspect, the invention embraces an indicia scanning assembly having a housing with a shock mount receiving space; and an elastomeric scan engine receiving shock mount positioned in the shock mount receiving space. The scan engine receiving shock mount has a first end with a scan engine receiving space.

In an embodiment of the indicia scanning assembly has a scan engine positioned in the scan engine receiving space.

In an embodiment, the scan engine receiving shock mount has an opposite second end with a scanning window receiving space.

In an embodiment, the indicia scanning assembly has a scanning window positioned in the scanning window receiving space at a predetermined angle to the scan engine.

In an embodiment, the scan engine receiving shock mount is made of a shock absorbing elastic material.

In an embodiment, the shock absorbing elastic material is silicone rubber.

In an embodiment, the housing includes an upper housing; and a lower housing having an inner surface and an outer surface.

In an embodiment, the lower housing includes a battery receiving space positioned on the outer surface or the inner surface.

In an embodiment, the indicia scanning assembly includes a battery positioned in the battery receiving space; and a battery over connected to the lower housing and covering the battery.

In an embodiment, the indicia scanning assembly includes a printed circuit board positioned between the lower housing and the upper housing, and electrically connected to the battery and the scan engine.

In an embodiment, the upper housing includes a button pad receiving space having a button pad positioned therein, the button pad being exposed to an outside on an outer surface and in contact with a feature of the printed circuit board on an opposite inner surface.

In an embodiment, the indicia scanning assembly has a wireless transmitting device connected to the printed circuit board.

In an embodiment, the indicia scanning assembly has a data transfer port positioned on the housing and connected to the printed circuit board.

In an aspect, the invention embraces a removable scan engine receiving shock mount with an elastomeric body having a first end with a scan engine receiving space.

In an embodiment the removable scan engine receiving shock mount includes a scan engine positioned in the scanning scan engine receiving space.

In an embodiment, the elastomeric body is elastomerically biased against the scan engine.

In an embodiment, the removable scan engine receiving shock mount includes an opposite second end having a scanning window receiving space.

In an embodiment, the removable scan engine receiving shock mount includes a scanning window positioned in the scanning window receiving space at a predetermined angle to the scan engine, and the elastomeric body is elastomerically biased against the scanning window.

In an embodiment, the scan engine receiving space and the scanning window receiving space together form a continuous receiving passageway having a separating bracket positioned circumferentially therebetween.

In an embodiment, the separating bracket includes a centrally positioned baffle post connecting two opposing sides of the separating bracket, the baffle post having a length approximately equal to a diameter of the separating bracket, and dividing the continuous receiving passageway into an emitter sub-passageway and a receiver sub-passageway.

In an embodiment, the removable scan engine receiving shock mount includes a scan engine securing cap connected to the first end and covering the scan engine.

The foregoing illustrative summary, as well as other exemplary objectives and/or advantages of the invention, and the manner in which the same are accomplished, are further explained within the following detailed description and its accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described by way of example, with reference to the accompanying Figures, of which:

FIG. 1 is an exploded perspective view of a scanner assembly;

FIG. 2 is an exploded perspective view of an upper housing of the scanner assembly;

FIG. 3 is an exploded perspective view of a scan engine receiving shock mount;

FIG. 4 is an exploded perspective view of a second end of a scan engine receiving shock mount;

FIG. 5 is an exploded perspective view of an opposite first end of the scan engine receiving shock mount shown in FIG. 4;

FIG. 6 is a cross-sectional view of the scan engine receiving shock mount along line C-C shown in FIG. 4;

FIG. 7 is a perspective view of the scanner assembly; and

FIG. 8 is a cross-sectional view of the scanner assembly along line L-L shown in FIG. 7.

DETAILED DESCRIPTION

In the embodiments shown in FIG. 1-8, an indicia scanning assembly 1 has a housing 100, a scan engine receiving shock mount 200, a scan engine 221, a scanning window 240, a printed circuit board 300, a battery 400, and a battery cover 150.

The housing 100 has an upper housing 110 and a complimentary lower housing 120. Both the upper housing 110 and the lower housing 120 are approximately half clam-shaped, and are connected together to form a hollow internal component receiving space (not labeled) therein. The internal component receiving space includes a shock mount receiving space 130 positioned proximate to a scanning end 101 a of the housing 100. In an embodiment, the housing is made of a suitable plastic material known to those skilled in the art. In an embodiment, the scanning end 101 a of the upper housing 110 is contoured to form an upper half of a shock mount receiving passageway 170.

In an embodiment shown in FIG. 2, the upper housing 110 has a button pad receiving space 160 extending through the upper housing 110 from an outer surface to an inner surface. A complimentarily shaped button pad 161 is positioned in the button pad receiving space 160. The button pad 161 has an outer surface 161 a exposed to an outside environment of the upper housing 110, and an opposite inner surface 161 b facing into the internal component receiving space of the housing 100.

In an embodiment shown in FIG. 1, the lower or upper housing 110,120 includes a optional housing gasket 102 extending circumferentially along a connecting edge 103 of the upper or lower housing 110,120.

In an embodiment, the upper housing 110 has a wireless transmitting device receiving passageway 410 a extending through the upper housing 110 from the outer surface to the inner surface. A complimentarily shaped wireless transmitting device 410 is positioned at least partially in the wireless transmitting device receiving passageway 410 a. In an embodiment, an indicator light (not labeled) of the wireless transmitting device 410 is positioned in the wireless transmitting device receiving passageway 410 a. In the embodiments shown in FIGS. 2 and 8, the wireless transmitting device receiving passageway 410 a is positioned distal to the scanning end 101 a on an opposite rear end 101 b, although those of ordinary skill in the art would appreciate that the wireless transmitting device receiving passageway 410 a may be positioned at other positions along the upper housing 110. In an embodiment, the wireless transmitting device 410 is a Bluetooth wireless transmitting device.

In an embodiment, the upper housing 110 has a battery indicator receiving passageway 430 a extending through the upper housing 110 from the outer surface to the inner surface. A complimentarily shaped battery indicator 430 is positioned at least partially in the battery indicator receiving passageway 430 a. In an embodiment, an indicator light (not labeled) of the battery indicator 430 is positioned in the battery indicatory receiving passageway 430 a. In the embodiments shown in FIGS. 2 and 8, the battery indicatory receiving passageway 430 a is positioned proximate to the scanning end 101 a, although those of ordinary skill in the art would appreciate that the battery indicatory receiving passageway 430 a may be positioned at other positions along the upper housing 110. In an embodiment, the battery indicator 430 displays a reading indicating the amount of battery power remaining in the device.

In the embodiments shown in FIGS. 2 and 8, the upper housing 110 has a data port receiving space (not labeled) positioned on the rear end 101 b, and a data port 420 positioned therein. In an embodiment, the data port 420 is a Universal Serial Bus (USB) port, although those of ordinary skill in the art would appreciate that the data port 420 can be any commonly known data port configuration.

In the embodiments shown in FIGS. 1 and 8, the lower housing 120 has an inner surface (not labeled) and an opposite outer surface (not labeled). The lower housing 120 has a battery receiving space 140 recessed into the outer surface on the rear end 101 b. In an embodiment, the scanning end 101 a of the lower housing 120 is contoured to form a lower half of the shock mount receiving passageway 170 that is complimentary to the upper half of the shock mount receiving passageway 170. The shock mount receiving passageway 170 has an approximate rectangular shape when the upper housing 110 is connected to the lower housing 120. In another embodiment, the shock mount receiving passageway 170 is approximately square, circular, oval, or other common shapes know to those of ordinary skill in the art.

In the embodiments shown in FIGS. 1 and 3-5, the scan engine receiving shock mount 200 (hereinafter referred to as “shock mount”) includes a shock mount body 201 having a first end 210 with a scan engine receiving space 220. The scan engine receiving space 220 has a complimentary shape to that of the scan engine 221, with the scan engine 221 being positioned therein.

The shock mount body 201 has an opposite second end 211 having a window receiving space 230. The scan engine receiving space 220 and the scanning window receiving space 230 together form a continuous receiving passageway 250 extending through the shock mount body 201, from the first end 210 to the second end 211.

A separating bracket 260 is positioned in the continuous receiving passageway 250, separating the scan engine receiving space 220 from the scanning window receiving space 230. The separating bracket 260 is integrally formed from the shock mount body 201, extending circumferentially as a continuous wall that protrudes from an inner surface of the continuous receiving passageway 250 a distance into the continuous receiving passageway 250. The separating bracket 260 functions as a flange, having a window abutting surface (not labeled), and a scan engine abutting surface (not labeled). The window abutting surface is set at a predetermined angle with respect to the scan engine abutting surface, with the predetermined angle being dependent on the type of scan engine 221 positioned in the scan engine receiving space 220. Those of ordinary skill in the art would appreciate that each type of scan engine 221 has an optimized angle at which the scanning window 240 is set in order for the scan engine 221 to operate.

The separating bracket 260 includes a baffle post 261. The baffle post 261 is connected to two opposing sides of the separating bracket 260, and has a length approximately equal to a diameter of the separating bracket 260. As shown for example, in the embodiment of FIG. 4, the baffle post 261 divides the continuous receiving passageway 250 into an emitter sub-passageway 262 and a receiver sub-passageway 263. In an embodiment, the baffle post 261 serves to block light scattering and interference between an emitter and a corresponding receiver of the installed scan engine 221.

The shock mount 200 is made from an elastic material such as silicone rubber, or other suitable elastic materials. The shock mount 200 can be formed by injection molding or other common methods known to those of ordinary skill in the art. The elasticity and viscosity of the elastic material can be varied depending on the application.

Generally, the scan engine 221 has an emitter device and a receiver device positioned on a functioning surface of an engine printed circuit board, and an electrical connector positioned on an opposite connecting surface of the engine printed circuit board (See for example, FIGS. 4 and 5). The functional surface of the scan engine 221 abuts the scan engine abutting surface of the separating bracket 260 when the scan engine 221 is positioned in the scan engine receiving space 220. The scan engine abutting surface serves as a positioning feature to aid in orienting the functional surface of the scan engine 221 at a predetermined angle with respect to the scanning window 240. The connecting surface of the scan engine 221 includes an electrical connector (not labeled) that connects to a connecting cable 310, such as a ribbon cable.

In the embodiments shown in FIGS. 6 and 8, the scan engine 221 is partially inserted into the scan engine receiving space 220, although those of ordinary skill in the art would appreciate that in other embodiments, the scan engine 221 can be fully inserted into the scan engine receiving space 220. When the scan engine 221 is positioned in the scan engine receiving space 220, the shock mount body 201 can be elastically expanded outwards, and thus be elastomerically biased against the inserted scan engine 221. Therefore, in an embodiment, the inserted scan engine 221 can be elastically held in the scan engine receiving space 220 by the inward force exerted by the shock mount body 201.

In an embodiment, the scan engine 221 can be a DB Hi2D, slim imager N6603, slim imager N6600, or any other scan engine known to those of ordinary skill in the art for use in hand held scanners.

In an embodiment, the scanning window 240 has a shape complimentary to the shape of the scanning window receiving space 230. As shown for example in FIGS. 1 and 6-8, the scanning window 240 is positioned in the scanning window receiving space 230 and abuts against the window abutting surface of the separating bracket 260. The window abutting surface positions the scanning window 240 at a predetermined angle with respect to the angle of the functional surface of the scan engine 221. When the scanning window 240 is positioned in the scanning window receiving space 230, the shock mount body 201 can be elastically expanded outwards, and thus be elastomerically biased against the inserted scanning window 240. Therefore, in an embodiment, the inserted scanning window 240 can be elastically held in the scanning window receiving space 230 by the inward force exerted by the shock mount body 201.

In the embodiments shown in FIGS. 4-6 and 8, the shock mount 200 optionally has a scanning engine securing cap 500 positioned on the first end 210, covering the inserted scan engine 221, and covering and sealing the scan engine receiving space 220. In an embodiment, when the scan engine 221 is partially inserted into the scan engine receiving space 220, the scanning engine securing cap 500 has an optional corresponding scan engine receiving chamber 220 a that receives a portion of the scan engine 221 positioned outside the scan engine receiving space 220, such as the scan engine printed circuit board. In an embodiment, the scan engine receiving chamber 220 a receives the electrical connector or the connecting cable 310 positioned on the connecting surface of the scan engine printed circuit board. In an embodiment, the scan engine securing cap 500 has a connecting cable receiving channel 510 through which the connecting cable 310 extends from the scan engine 221 to the printed circuit board 300. The scanning engine securing cap 500 can be made of the same material as the shock mount body 201; although those of ordinary skill in the art would appreciate that other suitable materials can be used in other embodiments.

The printed circuit board 300 has operative components, such as a corresponding electrical connector (See FIG. 8) that connects to the connecting cable 310 to provide communication between the printed circuit board 300 and the scan engine 221. In an embodiment, the wireless transmitting device 410 is electrically connected to the printed circuit board 300, either directly or through a cable (not shown). In an embodiment, the battery indicator 430 is electrically connected to the printed circuit board 300, either directly or through a cable (not shown). In another embodiment, the data port 420 is electrically connected to the printed circuit board 300, either directly or through a cable (not shown). In yet another embodiment, the printed circuit board 300 has a decoding module (not shown) that receives and decodes signals from the scan engine 221. In an embodiment, the printed circuit board 300 has one or more control buttons 301 positioned proximate to the button pad 161, the control buttons 301 being in contact with the inner surface 161 b of the button pad 161.

Assembly of the major components of the indicia scanning assembly 1 will now be described in detail with reference to the embodiments shown in FIGS. 1-8.

As shown in the embodiments of FIGS. 1, 3, and 8, the shock mount 200, having the scan engine 221 positioned in the scan engine receiving space 230 and the scanning window 240 positioned in the scanning window receiving space 230, is positioned into the shock mount receiving space 130 portion of the lower housing 120. A portion of the second end 211 of the shock mount 200 extends into the lower half of the shock mount receiving passageway 170. The printed circuit board 300 is positioned in the lower housing 120 over a portion of the shock mount 220, and is connected to the connecting cable 310 extending from the scan engine 221. The battery 400 is positioned in the battery receiving space 140 and is electrically connected to the printed circuit board 300. The battery cover 150 is connected to the lower housing 120, covering the battery 400 and the battery receiving space 140. An optional battery cover gasket 151 is positioned along a battery cover connecting edge 152 between the lower housing 120 and the battery cover 150, providing a seal therebetween (See FIG. 1).

The upper housing 110 is then connected to the lower housing 120 to form the internal component receiving space that includes the shock mount receiving space 220 and the installed shock mount 200, as well as the printed circuit board 300, and other various components described in the above embodiments and shown in FIGS. 1-8, as well as various other components known to those of ordinary skill in the art. A portion of the second end 211 of the shock mount 200 extends into the upper half of the shock mount receiving passageway 170. Additionally, the optional housing gasket 102 is positioned along the upper and lower housing's 110,120 connecting edges 103, providing a seal therebetween.

In an embodiment, a volume of the shock mount 200 is larger than a volume of the shock mount receiving space 130. When the shock mount 200 is positioned in the shock mount receiving space 130 and the upper housing 110 is connected to the lower housing 120, the shock mount 200 is compressed a predetermined amount, acting as a sealing gasket to provide a liquid Ingress Protection (IP) seal rating for the indicia scanning assembly 1, as determined by IEC standard 60529. In an embodiment, the indicia scanning assembly 1 has an IP sealing rating of 1-4. In an embodiment, the indicia scanning assembly 1 has an IP sealing rating of 1. In another embodiment, the indicia scanning assembly 1 has an IP sealing rating of 2. In yet another embodiment, the indicia scanning assembly 1 has an IP sealing rating of 3. In another embodiment, the indicia scanning assembly 1 has an IP sealing rating of 4.

In an embodiment, where the indicia scanning assembly 1 has an installed shock mount 200 with a first scan engine 221, the installed shock mount 200 is removable from the indicia scanning assembly 1 by disconnecting the upper housing 110 from the lower housing 120. A different shock mount 200 having a second scan engine 221 with a different optical sensor mechanism than the first scan engine 221, can be installed in the scan engine receiving space 220. Thus, by providing a shock mount 220 with a standard volume and size, the indicia scanning assembly 1 can accept a wide variety of scan engine 221 and scanning window 240 combinations by simply redesigning the shock mount 220.

One of the many advantages of the indicia scanning assembly 1 is that the housing 100 is universal, and the expensive and long lead times for creating a new housing mold specific to a single type of scan engine 221, as well as housing 100 features, such as texture, molded text, and co-molds, is eliminated. A new scan engine 221 can be integrated into the universal housing 100 by simply redesigning a new shock mount 200 that receives the new scan engine 221 and scanning window 240 combination. The new shock mount mold for the new shock mount 200 is relatively inexpensive, because of the simplicity of the shock mount 200 compared to the housing 100, and consequently, has a far shorter development lead time.

Another of the many advantages of the indicia scanning assembly 1 is that if a scan engine 221 becomes inoperable, the installed shock mount 220 can be removed and replaced with a new shock mount 220 with a functioning scan engine 221.

Another of the many advantages of the indicia scanning assembly 1 over conventional attempts to design interchangeable scan engines in a universal housing is that the complexity of the scan engine-bracket-printed circuit board-housing-bezel-window configuration is greatly reduced. Instead, in the embodiments discussed above, since the shock mount 200 generally utilizes a scan engine 200-separating bracket 260-scanning window 240 configuration, the complexity of the shock mount 200 is greatly reduced. Additionally, the reduced number of interfaces in the shock mount 200 compared to the conventional designs, avoids the cumulative effects of stack up tolerance, increases manufacturing yield, avoids the need for extensive quality control modifications during manufacturing, among others.

To supplement the present disclosure, this application incorporates entirely by reference the following commonly assigned patents, patent application publications, and patent applications:

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In the specification and/or figures, typical embodiments of the invention have been disclosed. The invention is not limited to such exemplary embodiments. The use of the term “and/or” includes any and all combinations of one or more of the associated listed items. The figures are schematic representations and so are not necessarily drawn to scale. Unless otherwise noted, specific terms have been used in a generic and descriptive sense and not for purposes of limitation. 

1. An indicia scanning assembly, comprising: a housing having a shock mount receiving space; and an elastomeric scan engine receiving shock mount positioned in the shock mount receiving space, and having a first end with a scan engine receiving space, and an opposite second end with a scanning window receiving space; and wherein the scan engine receiving space and the scanning window receiving space together form a passageway having a separating bracket positioned between the scan engine receiving space and the scanning window receiving space.
 2. The indicia scanning assembly of claim 1, further comprising a scan engine positioned in the scan engine receiving space.
 3. (canceled)
 4. The indicia scanning assembly of claim 1, further comprising a scanning window positioned in the scanning window receiving space at a predetermined angle to the scan engine.
 5. The indicia scanning assembly of claim 4, wherein the scan engine receiving shock mount is made of a shock absorbing elastic material.
 6. The indicia scanning assembly of claim 5, wherein the shock absorbing elastic material is silicone rubber.
 7. The indicia scanning assembly of claim 5, wherein the housing includes: an upper housing; and a lower housing having an inner surface and an outer surface. 8-13. (canceled)
 14. A removable scan engine receiving shock mount, comprising: an elastomeric body having a first end with a scan engine receiving space; and an opposite second end having a scanning window receiving space; and wherein the scan engine receiving space and the scanning window receiving space together form a passageway having a separating bracket positioned between the scan engine receiving space and the scanning window receiving space.
 15. The removable scan engine receiving shock mount of claim 14, further comprising a scan engine positioned in the scan engine receiving space.
 16. The removable scan engine receiving shock mount of claim 15, wherein the elastomeric body is elastomerically biased against the scan engine.
 17. (canceled)
 18. The removable scan engine receiving shock mount of claim 14, further comprising a scanning window positioned in the scanning window receiving space at a predetermined angle to the scan engine, and wherein the elastomeric body is elastomerically biased against the scanning window.
 19. (canceled)
 20. The removable scan engine receiving shock mount of claim 14, further comprising a baffle post, the baffle post configured to divide the passageway into an emitter sub-passageway and a receiver sub-passageway.
 21. An indicia scanning assembly kit, comprising: a housing having a universal shock mount receiving space; and one or more elastomeric scan engine receiving shock mounts, each configured to be positioned in the universal shock mount receiving space, and each having a first end with a scan engine receiving space configured to receive a scan engine, an opposite second end with a scanning window receiving space configured to receive a window, and a passageway having a separating bracket positioned between the scan engine receiving space and the scanning window receiving space; wherein the separating bracket comprises a flange having a window abutting surface and a scan engine abutting surface, the window abutting surface being set at a predetermined angle with respect to the scan engine abutting surface, the separating bracket thereby being configured to receive a window abutting the window abutting surface at the predetermined angle with respect to the scan engine abutting the scan engine abutting surface, said predetermined angle depending on the type of scan engine intended to be positioned in the elastomeric scan engine receiving shock mount.
 22. The indicia scanning assembly kit of claim 21, further comprising a plurality of the elastomeric scan engine receiving shock mounts, each corresponding to a plurality of different scan engines, each of the scan engines having a different scanning mechanisms and/or a different optical sensor.
 23. The indicia scanning assembly kit of claim 22, wherein each of the plurality of the elastomeric scan engine receiving shock mounts has a predetermined angle with respect to the scan engine abutting surface that differs from at least one of the other elastomeric scan engine receiving shock mounts.
 24. The indicia scanning assembly kit of claim 21, further comprising a plurality of scan engines, each scan engine from the plurality corresponding to at least one of the elastomeric scan engine receiving shock mounts having a scan engine receiving space configured to receive the scan engine.
 25. The indicia scanning assembly kit of claim 24, wherein the plurality of scan engines each have a scanning mechanisms and/or an optical sensor that differs from at least one of the other scan engines.
 26. The indicia scanning assembly kit of claim 21, wherein the scan engine abutting surface is further configured to receive a scan engine abutting the scan engine abutting surface at a predetermined angle with respect to the window abutting the window abutting surface, said predetermined angle depending on the type of scan engine intended to be positioned in the elastomeric scan engine receiving shock mount.
 27. The indicia scanning assembly kit of claim 21, wherein the scanning window receiving space is configured to secure a window abutting the window butting surface at least in part by elastomeric bias exerted against the window.
 28. The indicia scanning assembly kit of claim 21, wherein the shock mount further comprises a baffle post, the baffle post configured to divide the passageway into an emitter sub-passageway and a receiver sub-passageway.
 29. The indicia scanning assembly kit of claim 21, further comprising a securing cap configured to mate with the one or more elastomeric scan engine receiving shock mounts, wherein the securing cap is further configured to receive a portion of the scan engine.
 30. A method of fitting a plurality of different types of scan engines in an indicia scanning assembly, comprising: providing an indicia scanning assembly housing, the housing having a universal shock mount receiving space; and providing for each one of a plurality of different types of scan engines, an elastomeric scan engine receiving shock mount configured to be positioned in the universal shock mount receiving space, the elastomeric scan engine receiving shock mount having: a first end with a scan engine receiving space configured to receive a respective scan engine from the plurality; an opposite second end with a scanning window receiving space configured to receive a window; and a passageway between the scan engine receiving space and the scanning window receiving space, the passageway having a separating bracket positioned between the scan engine receiving space and the scanning window receiving space; wherein the separating bracket comprises a flange having a window abutting surface and a scan engine abutting surface, the window abutting surface being set at a predetermined angle with respect to the scan engine abutting surface, the separating bracket thereby being configured to receive a window abutting the window abutting surface at the predetermined angle with respect to the respective scan engine from the plurality abutting the scan engine abutting surface, the predetermined angle depending on the respective scan engine from the plurality intended to be positioned in the elastomeric scan engine receiving shock mount; selecting from the plurality, a scan engine and a corresponding elastomeric scan engine receiving shock mount; fitting the selected scan engine in the scan engine receiving space abutting the scan engine abutting surface of the corresponding elastomeric scan engine receiving shock mount, and fitting a window in the window receiving space abutting the window abutting surface of the corresponding elastomeric scan engine receiving shock mount; and installing the selected elastomeric scan engine receiving shock mount into the universal shock mount receiving space.
 31. The method of claim 30, wherein each one of the plurality of different types of scan engines has a scanning mechanisms and/or an optical sensor that differs from at least one of the other scan engines.
 32. The method of claim 30, wherein each one of the elastomeric scan engine receiving shock mounts has a predetermined angle with respect to the scan engine abutting surface that differs from at least one of the other elastomeric scan engine receiving shock mounts.
 33. The method of claim 30, wherein the window abutting the window butting surface is secured at least in part by elastomeric bias exerted against the window.
 34. The method of claim 30, wherein the shock mount further comprises a baffle post, the baffle post configured to divide the passageway into an emitter sub-passageway and a receiver sub-passageway.
 35. The method of claim 30, further comprising mating a securing cap with the selected elastomeric scan engine receiving shock mount, wherein the securing cap is configured to receive a portion of at least one of the plurality of different types of scan engines. 